A numerical study of super-resolution through fast 3D wideband algorithm for scattering in highly-heterogeneous media

We present a wideband fast algorithm capable of accurately computing the full numerical solution of the problem of acoustic scattering of waves by multiple finite-sized bodies such as spherical scatterers in three dimensions. By full solution, we mean that no assumption (e.g. Rayleigh scattering, geometrical optics, weak scattering, Born single scattering, etc.) is necessary regarding the properties of the scatterers, their distribution or the background medium. The algorithm is also fast in the sense that it scales linearly with the number of unknowns. We use this algorithm to study the phenomenon of super-resolution in time-reversal refocusing in highly-scattering media recently observed experimentally (Lemoult et al., 2011), and provide numerical arguments towards the fact that such a phenomenon can be explained through a homogenization theory.     

基于散射信号的超分辨光学相减显微镜

现有的光学超分辨显微成像技术主要依赖于特殊的荧光标记物,其对于大多数非荧光样品的超分辨成像就变得无能为力。因此我们提出将光学相减显微技术应用到非荧光样品的成像当中,利用普通共聚焦光斑和面包圈型光斑分别激发样品的散射光成像,从而得到样品同一区域的两幅图像,再通过图像相减的方法提高了图像空间分辨率。不同于一般的超分辨成像方法,这种光学相减显微镜不需要特殊的样品预处理过程,同时两次成像的激发光强度可以保持在一个较低水平,避免了样品损伤的影响。随后金纳米小球和有机聚合物微丝的散射成像实验证明了光学相减显微镜可以将空间分辨率提高到215 nm (0.33λ, 1λ = 650 nm),并且通过探测散射信号得到更多的样品细节信息。     

细胞膜上信号转导蛋白的单分子成像与分析

结合本课题组的研究工作, 介绍了单分子荧光成像原理、 荧光标记方法及数据分析方法, 并进一步综述了单分子荧光成像在几种重要的膜蛋白信号转导分子机制和相关药物研究中的进展.     

高分辨和超分辨光学成像技术在空间和生物中的应用

大到天文光学望远镜观察浩瀚的宇宙, 小到光学显微镜探察细微的纳米世界, 光学成像技术在人类探索和发现未知世界奥秘的活动中扮演着至关重要的角色. 看得更远、看得更细、看得更清楚是人们不断追求的目标. 传统光学理论已证明所有经典光学系统都是一个衍射受限系统, 即光学系统空间分辨率的物理极限是由光的波长和系统的相对孔径(或数值孔径)决定的. 能否突破这个极限？能否不断提高光学系统的成像分辨率？围绕着这个问题, 本文综述了近年来开展的各种光学高分辨和超分辨成像技术, 及其在空间探测和生物领域中的应用.     

Super-resolved parallel MRI by spatiotemporal encoding

Recent studies described an “ultrafast” scanning method based on spatiotemporal (SPEN) principles. SPEN demonstrates numerous potential advantages over EPI-based alternatives, at no additional expense in experimental complexity. An important aspect that SPEN still needs to achieve for providing a competitive ultrafast MRI acquisition alternative, entails exploiting parallel imaging algorithms without compromising its proven capabilities. The present work introduces a combination of multi-band frequency-swept pulses simultaneously encoding multiple, partial fields-of-view, together with a new algorithm merging a Super-Resolved SPEN image reconstruction and SENSE multiple-receiving methods. This approach enables one to reduce both the excitation and acquisition times of sub-second SPEN acquisitions by the customary acceleration factor R, without compromises in either the method’s spatial resolution, SAR deposition, or capability to operate in multi-slice mode. The performance of these new single-shot imaging sequences and their ancillary algorithms were explored and corroborated on phantoms and human volunteers at 3 T. The gains of the parallelized approach were particularly evident when dealing with heterogeneous systems subject to major T₂/T₂* effects, as is the case upon single-scan imaging near tissue/air interfaces.     

Improving the imaging intensity of a photonic crystal flat lens by an antireflection method

In this paper, a two-dimensional photonic crystal (PC) consisting of a triangular lattice of silicon rods in air is studied theoretically. Equal-frequency contours (EFCs) analysis shows that this PC structure exhibits an effective refractive index n_eff = −1 at a normalized frequency ω=0.30×2πc/a$\omega =0.30\times 2\pi c/a$. A superlens effect is demonstrated using this PC structure by the finite-difference time-domain (FDTD) simulation. An antireflection layer (ARL) is introduced into the PC slab surface in order to achieve a high-intensity image. Two point sources imaging process is also simulated both in the case of a perfect PC structure and in the case of a PC structure with an ARL. The results show that the method of introducing the ARL into the PC surface is effectual for improving both the intensity of the image and the capability of the super-resolution of two sources, which are in accord with the coupled-mode theory analysis. Theoretical study implies that the surface defect modes play an important role in enhancing the transmitted intensity of energy flow.